Communication device working on unlicensed frequency band and method performed by the same

ABSTRACT

Embodiments of the present disclosure relates to a communication device working on unlicensed frequency band and a method for executing the same. The method comprises: determining a mapping relationship between multiple quality of service (QoS) priority classes and multiple Listen-Before-Talk (LBT) priority classes, wherein the multiple QoS priority classes are in one-to-one correspondence with multiple QoS requirements; and transmitting radio traffic based on the mapping relationship. Embodiments of the present disclosure proposes the mapping relationship between LBT priority class and various QoS priority classes associated with different radio traffic types and presents signaling design and exchange related to the mapping relationship.

FIELD

The present invention relates generally to the field of wirelesscommunications, and more particularly to a communication device workingon an unlicensed frequency band and a method performed by the same.

BACKGROUND

Operators are using unlicensed frequency bands to augment their servicessupplies, which is being studied in 3GPP and calledLicensed-Assisted-Access (LAA). When LTE works in unlicensed frequencybands, the key issue is to ensure fair coexistence with Wi-Fi system andother systems.

Currently, Wi-Fi system designs Enhanced Distributed Channel Access(EDCA) to support prioritized quality of service (QoS), wherein fouraccess categories (ACs) are defined. Each AC is characterized byspecific values for a set of access parameters (e.g., defer period,contention window size, transmit opportunity) that statisticallyprioritize channel access for one AC over another.

Naturally, LAA systems coexisted with Wi-Fi system should also supportQoS with multiple Listen-Before-Talk (LBT) priority classes. DownlinkLBT procedure for LTE-LAA has been discussed in 3GPP and it recommends aLBT mechanism operating similar to channel access in Wi-Fi for LAAdownlink transmission.

Until now, LAA lacks solutions in which multiple QoS requirements areprocessed using LBT operation. Therefore, it becomes particularlyimportant to design a mapping relationship between multiple QoS priorityclasses and multiple Listen-Before-Talk (LBT) priority classes andpotential signaling to support different QoS in LTE-LAA.

SUMMARY

In light of the above existing problems in the prior art, embodiments ofthe present disclosure aim at providing a communication device workingon an unlicensed frequency band and a method performed by the same, tosolve the above and other issues in the prior art. The embodiments ofthe present disclosure provide the mapping relationship betweendifferent QoS priority classes associated with various radio traffictypes and LBT priority classes and propose signaling design andsignaling exchange related to the mapping relationship.

In one aspect of the present disclosure, it provides a method performedby a communication device working on an unlicensed frequency band. Themethod can include: determining a mapping relationship between multipleQoS priority classes and multiple Listen-Before-Talk (LBT) priorityclasses, wherein the multiple QoS priority classes are in one-to-onecorrespondence with multiple QoS requirements; and transmitting radiotraffic based on the mapping relationship.

In some embodiments, the mapping relationship can comprise: mapping eachQoS priority class only to one LBT priority class.

In some embodiments, the mapping relationship can comprise: mapping eachQoS priority class to a plurality of LBT priority classes. In theseembodiments, transmitting radio traffic based on the mappingrelationship can comprise: selecting one of a plurality of LBT priorityclasses to which the QoS priority class is mapped to transmit radiotraffic.

In some embodiments, the mapping relationship can comprise: causing aLBT priority class to which a higher QoS priority class is mapped to benot lower than a LBT priority class mapped to by a lower QoS priorityclass.

In some embodiments, the mapping relationship can be predefined.

In some embodiments, the mapping relationship can be configurable. Inthese embodiments, there may be a default mapping relationship. In theseembodiments, the mapping relationship can be semi-staticallyconfigurable.

In some embodiments, the mapping relationship can be cell-specific.

In some embodiments, the mapping relationship can be userequipment-specific.

In some embodiments, if each QoS priority class is only mapped to oneLBT priority class, transmitting radio traffic based on the mappingrelationship can comprise: when the radio traffic is associated with atleast two LBT priority classes of the multiple LBT priority classes,transmit radio traffic using a lower LBT priority class of the at leasttwo LBT priority classes.

In some embodiments, if the communication device is a base station,determining a mapping relationship between multiple QoS priority classesand multiple Listen-Before-Talk (LBT) priority classes can comprise:configuring a mapping relationship between multiple QoS priority classesand multiple Listen-Before-Talk (LBT) priority classes. In theseembodiments, the method can further comprise: transmitting the mappingrelationship to user equipment. In these embodiments, transmitting themapping relationship to user equipment can comprise: transmitting themapping relationship to the user equipment via a broadcast message. Inthese embodiments, transmitting the mapping relationship to userequipment can comprise: transmitting the mapping relationship toparticular user equipment via a user equipment-specific message. Inthese embodiments, the method can further comprise: receiving, from aneighboring base station, a mapping relationship used by the neighboringbase station; and configuring the mapping relationship based on mappingrelationship used by the neighboring base station.

In some embodiments, if the communication device is user equipment,determining a mapping relationship between multiple QoS priority classesand multiple Listen-Before-Talk (LBT) priority classes can comprise:receiving the mapping relationship from a base station. In theseembodiments, receiving the mapping relationship from a base station cancomprise: receiving the mapping relationship from a base station via abroadcast message. In these embodiments, receiving the mappingrelationship from a base station can comprise: receiving the mappingrelationship from a base station through a user equipment-specificmessage.

In some embodiments, the QoS priority class can comprise Quality ClassIdentifier QCI.

In some embodiments, the QoS priority class can comprise Data RadioBearer DRB and/or Signaling Radio Bearer SRB.

In some embodiments, the QoS priority class can comprise a physicallayer signaling.

In a second aspect of the present disclosure, it provides acommunication device working on an unlicensed frequency band. Thecommunication device can comprise: a determining unit configured todetermine a mapping relationship between multiple QoS priority classesand multiple Listen-Before-Talk (LBT) priority classes, wherein themultiple QoS priority classes are in one-to-one correspondence withmultiple QoS requirements; and a transmitting unit configured totransmit radio traffic based on the mapping relationship.

In some embodiments, the mapping relationship can comprise: mapping eachQoS priority class only to one LBT priority class.

In some embodiments, the mapping relationship can comprise: mapping eachQoS priority class to a plurality of LBT priority classes. In theseembodiments, the transmitting unit can be further configured to: selectone of a plurality of LBT priority classes to which QoS priority classis mapped to transmit radio traffic.

In some embodiments, the mapping relationship can comprise: causing aLBT priority class to which a higher QoS priority class is mapped to benot lower than a LBT priority class to which a lower QoS priority classis mapped .

In some embodiments, the mapping relationship can be predefined.

In some embodiments, the mapping relationship can be configurable. Inthese embodiments, there may be a default mapping relationship. In theseembodiments, the mapping relationship can be semi-staticallyconfigurable.

In some embodiments, the mapping relationship can be cell-specific.

In some embodiments, the mapping relationship can be userequipment-specific.

In some embodiments, if each QoS priority class is only mapped to oneLBT priority class, the transmitting unit can be further configured:when the radio traffic is associated with at least two LBT priorityclasses of the multiple LBT priority classes, transmit radio trafficusing a lower LBT priority class of the at least two LBT priorityclasses.

In some embodiments, the communication device can be a base station, andthe determining unit can be further configured to: configure a mappingrelationship between multiple QoS priority classes and multipleListen-Before-Talk (LBT) priority classes. In these embodiments, thetransmitting unit can be further configured to: transmit the mappingrelationship to user equipment. In these embodiments, the transmittingunit can be further configured to: transmit the mapping relationship tothe user equipment via a broadcast message. In these embodiments, thetransmitting unit can be further configured to: transmit the mappingrelationship to particular user equipment via a user equipment-specificmessage. In these embodiments, the communication device can furthercomprise: a receiving unit configured to receive, from a neighboringbase station, a mapping relationship used by the neighboring basestation; and the determining unit is further configured to configure themapping relationship based on mapping relationship used by theneighboring base station.

In some embodiments, the communication device can be user equipment, thedetermining unit can be further configured to: receive the mappingrelationship from a base station. In these embodiments, the determiningunit can be further configured to: receive the mapping relationship froma base station via a broadcast message. In these embodiments, thedetermining unit can be further configured to: receive the mappingrelationship from a base station through a user equipment-specificmessage.

In some embodiments, the QoS priority class can comprise Quality ClassIdentifier QCI.

In some embodiments, the QoS priority class can comprise Data RadioBearer DRB and/or Signaling Radio Bearer SRB.

In some embodiments, the QoS priority class can comprise a physicallayer signaling.

BRIEF DESCRIPTION OF THE DRAWINGS

With reference to the drawings and the detailed description below, it iseasy to understand the above and other objectives, features andadvantages of the embodiments of the present disclosure. In thedrawings, multiple embodiments of the present disclosure are shown in anillustrative yet non-restrictive manner, wherein:

FIG. 1 illustratively shows a method performed by a communication deviceworking on an unlicensed frequency band according to the embodiments ofthe present disclosure.

FIG. 2 illustratively shows default EDCA access parameters for 802.11a,802.11g and 802.11n physical layers of Wi-Fi system.

FIG. 3 illustratively shows an example of LBT priority class for LAAsystem.

FIG. 4 illustratively shows standardized QCI characteristics.

FIG. 5 illustratively shows a diagram of a mapping mode between QCI andLBT priority class.

FIG. 6 illustratively shows a specific example of the mappingrelationship between QCI and LBT priority class.

FIG. 7 illustratively shows a diagram of another mapping mode betweenQCI and LBT priority class.

FIG. 8 illustratively shows a diagram of a mapping mode between DRB andLBT priority class.

FIG. 9 illustratively shows a specific example of the mappingrelationship between DRB and LBT priority class.

FIG. 10 illustratively shows a communication device working on anunlicensed frequency band according to the embodiments of the presentdisclosure.

DETAILED DESCRIPTION

The principle and spirit of the present disclosure will be describedwith reference to the multiple exemplary embodiments shown in thedrawings. It is to be appreciated that describing these specificembodiments only aims to provide a better understanding for thoseskilled in the art and implement the present disclosure, rather thanrestrict the scope of the present disclosure in any manners.

FIG. 1 illustratively shows a method 100 performed by a communicationdevice working on an unlicensed frequency band according to theembodiments of the present disclosure.

As shown in FIG. 1, the method 100 proceeds to step 101 after the start.In step 101, the communication device working on an unlicensed frequencyband can determine a mapping relationship between multiple QoS priorityclasses and multiple Listen-Before-Talk (LBT) priority classes, whereinthe multiple QoS priority classes are in one-to-one correspondence withmultiple QoS requirements. Those skilled in the art can understand thatin step 101, QoS priority class can be any parameters that embodypriority classes for QoS and meet the condition that the multiple QoSpriority classes are in one-to-one correspondence with multiple QoSrequirements. In this regard, QoS priority class may comprise, forexample, Quality Class Indicator QCI, or Data Radio Bearer DBR and/orSignaling Radio Bearer SRB, or physical layer signaling for the purposeof illustration. When the QoS priority class comprises QCI, itscorresponding multiple QoS requirements can comprise resource types,priority classes, packet delay budget and packet error loss rate etc.

As an example, the communication device in step 101 can be acommunication device in LAA system. As described above, LAA systemscoexisted with Wi-Fi system should also support QoS with multipleListen-Before-Talk (LBT) priority classes. In this regard, FIG. 2illustratively shows default EDCA access parameters for 802.11a, 802.11gand 802.11n physical layers of Wi-Fi system. Furthermore, in FIG. 2, thearbitration inter-frame space (AIFS) for a particular access category isdefined by the following equation: AIFS[AC]=SIFSTime+AIFSN[AC]*SlotTime.

In another aspect, downlink LBT procedure for LTE-LAA has been discussedin 3GPP and it recommends a LBT mechanism operating similar to channelaccess in Wi-Fi for LAA downlink transmission. In this regard, FIG. 3illustratively shows an example of LBT priority class for LAA system,wherein it depicts the minimum contention window size, the maximumcontention window size and AIFS for characterizing LBT priority class.

It is seen from FIGS. 2 and 3 that LBT priority class and EDCA accessparameter of Wi-Fi system are extremely similar. Therefore, in order toapply LBT priority class into LTE, it requires mapping multiple QoSpriority classes to multiple Listen-Before-Talk (LBT) priority classes,such that the communication device working on an unlicensed frequencyband can transmit radio traffic in the unlicensed frequency band basedon LBT priority class.

Next, method 100 proceeds to step 102. In step 102, the communicationdevice working on an unlicensed frequency band can transmit radiotraffic based on the mapping relationship. Those skilled in the art canunderstand that the communication device working on an unlicensedfrequency band needs to transmit radio traffic based on LBT priorityclass. Therefore, the communication device working on an unlicensedfrequency band can further determine LBT priority class based on thedetermined mapping relationship in step 101 through QoS priority classof radio traffic to be transmitted.

According to some embodiments of the present disclosure, the mappingrelationship can comprise: mapping each QoS priority class only to oneLBT priority class. In these embodiments, the communication deviceworking on an unlicensed frequency band can solely determine the LBTpriority class used for transmitting radio traffic on the unlicensedfrequency band from QoS priority class of radio traffic to betransmitted based on the mapping relationship and then performtransmission according to parameters of the LBT priority class.

According to some embodiments of the present disclosure, the mappingrelationship can comprise: mapping each QoS priority class to aplurality of LBT priority classes, i.e., a range of LBT priority classis defined for each QoS priority class. In these embodiments, the basestation, based on its own information, decides and uses one LBT priorityclass for data type corresponding to QoS priority class. Therefore, inthese embodiments, step 102 can further comprise: selecting one of aplurality of LBT priority classes to which QoS priority class is mappedto transmit radio traffic. Those skilled in the art can understand thatthe communication device can, based on parameters such as channelcondition and cell loading, select a suitable one from the multiple LBTpriority classes to transmit radio traffic because QoS priority classcan be mapped to multiple LBT priority classes.

According to some embodiments of the present disclosure, the mappingrelationship can comprise: causing a LBT priority class to which ahigher QoS priority class is mapped to be not lower than a LBT priorityclass to which a lower QoS priority class is mapped. Those skilled inthe art can understand that the QoS priority class per se representspriority of the traffic to be transmitted. Therefore, it shouldpreferably map a higher QoS priority class to a higher LBT priorityclass, so as to transmit radio traffic with higher QoS priority classusing a higher LBT priority class. That is, it should preferably cause aLBT priority class to which a higher QoS priority class is mapped to benot lower than a LBT priority class to which a lower QoS priority classis mapped.

According to some embodiments of the present disclosure, the mappingrelationship can be predefined. In these embodiments, any communicationdevices are aware of the predefined mapping relationship and transmitradio traffic according to the predefined mapping relationship. In thespecific example of LTE-LAA, it means that there is completely no needto design signaling for mapping relationship interaction regardingLTE-LAA uplink and downlink.

According to some embodiments of the present disclosure, the mappingrelationship is configurable. In these embodiments, the mappingrelationship is not predefined, but is configured by the communicationdevice working on an unlicensed frequency band based on its channelcondition and cell loading etc. Besides, the mapping relationship can beconfigured or adjusted as the parameters vary along time.

In these embodiments, the mapping relationship is configurable, whereinthere may be a default mapping relationship. That is, those skilled inthe art can understand that the default mapping relationship is alwaysused by the communication device working on an unlicensed frequency bandif no updated relationship is configured. In addition, the mappingrelationship can be semi-statically configurable, i.e., thecommunication device working on an unlicensed frequency band canconfigure or adjust the mapping relationship over a longer time span.

For example, if the communication device is a base station, the basestation, based on its cell loading, channel condition and otherinformation, can change the mapping relationship. For the downlink LAA,when downlink cell load becomes pretty high and the base station sensesthat the carrier is pretty free, a smaller contention window size andthe mapping relationship corresponding to a smaller value of ClearChannel Assessment CCA slots in the defer period can be used to expeditethe channel access. As a typical example, when the base station sensesthat the channel is pretty free for a time while a certain low priorityclass traffic is far larger than other traffic types, the LBT priorityclass corresponding to the low priority class traffic type can beadjusted, e.g., to use the little higher priority level to expedite thechannel access.

According to some embodiments of the present disclosure, the mappingrelationship can be cell-specific and user equipment-specific. In otherwords, one cell can correspond to one mapping relationship or one userequipment can correspond to one mapping relationship, such that a morerefined priority class configuration can be realized in radiocommunication systems. If the mapping relationship is userequipment-specific, the base station can determine the mappingrelationship based on the channel condition and cell loading etc.reported by the user equipment. For example, when the downlink cell loadis low, the base station is configured such that the mappingrelationship of a smaller contention window is broadcasted to all serveduser equipment. The process can also be equipment-specific, e.g., theuser equipment at a little high congestion situation can be configuredwith a mapping relationship of a larger contention window.

According to some embodiments of the present disclosure, if each QoSpriority class is only mapped to one LBT priority, step 102 can furthercomprise: when the radio traffic is associated with at least two LBTpriority classes of the multiple LBT priority classes, transmit radiotraffic using a lower LBT priority class of the at least two LBTpriority classes. In these embodiments, the radio traffic which isneeded to be transmitted by the communication device working on anunlicensed frequency bands involves with multiple LBT priority classes.For example, in a specific example of LTE-LAA, the radio traffic to betransmitted can comprise traffic of different priority requirements,such as audio and video and they respectively correspond to differentLBT priority classes. Therefore, the radio traffic relates to multipleLBT priority classes. In such case, the radio traffic should betransmitted using the lowest LBT priority class, in order to fairlyco-exist with other communication systems in the unlicensed frequencyband.

According to some embodiments of the present disclosure, if thecommunication device is a base station, step 101 can comprise:configuring a mapping relationship between multiple QoS priority classesand multiple Listen-Before-Talk (LBT) priority classes. In theseembodiments, the mapping relationship is not pre-defined thus itrequires the base station itself to configure the mapping relationship.In these embodiments, method 100 can further comprise: transmitting themapping relationship to user equipment. If the mapping relationship isnot pre-defined, the user equipment cannot determine the mappingrelationship on its own. Therefore, in such case, the base station needsto transmit the mapping relationship determined by itself to the userequipment, to facilitate the user equipment to transmit radio trafficbased on the mapping relationship determined by the base station.Furthermore, in these embodiments, transmitting the mapping relationshipto the user equipment can comprise: transmitting the mappingrelationship to the user equipment via a broadcasted message, whichmeans that all user equipment use the received mapping relationship at atime until the new or updated broadcast information is received. In oneembodiment, the signaling can be included in System InformationBroadcasting (SIB). Alternatively, transmitting the mapping relationshipto user equipment can comprise: transmitting the mapping relationship toparticular user equipment via a user equipment-specific message. In oneembodiment, the message can be RRC signaling, MAC command or othersuitable messages.

According to some embodiments of the present disclosure, if thecommunication is a base station and the mapping relationship isconfigurable, method 100 can further comprise: receiving, from aneighboring base station, a mapping relationship used by the neighboringbase station; and configuring the mapping relationship based on mappingrelationship used by the neighboring base station. In one embodiment,the selected mapping relationship can be signaled between neighboringbase stations via X2/S1 interface for implementing self-organization andself-configuration of the network. The receiving base station cansemi-statically change or configure the mapping relationship based onits own cell status as well as the LBT parameters of its neighboringbase station. In one embodiment, cell-specific mapping relationships canbe exchanged between base stations. For example, when a second basestation receives mapping relationship information of a first basestation, it can adjust its mapping relationship accordingly taking itsown information into account. In one embodiment, when the user equipmentis moved from one cell to another cell, the user equipment-specificmapping relationship can be transmitted from the source base station totarget base station for further LBT priority configuration.

According to some embodiments of the present disclosure, if thecommunication device is user equipment, step 101 can comprise: receivingthe mapping relationship from the base station. In these embodiments,the mapping relationship is not pre-defined and the user equipmentcannot determine the mapping relationship accordingly. Therefore, insuch case, the user equipment needs to receive from the base station themapping relationship determined by it, to facilitate the user equipmentto transmit radio traffic based on the mapping relationship determinedby the base station. In this regard, according to some embodiments ofthe present disclosure, the mapping relationship received from the basestation can comprise: receiving the mapping relationship from the basestation via a broadcast message. Alternatively, receiving the mappingrelationship from the base station can comprise: receiving the mappingrelationship from the base station via a user equipment-specificmessage.

According to some embodiments of the present disclosure, the QoSpriority class can comprise Quality Class Identifier QCI. Alternatively,the QoS priority class can comprise Data Radio Bearer DRB and/orSignaling Radio Bearer SRB. Alternatively, the QoS priority class cancomprise a physical layer signaling, e.g., downlink control signaling.

After going through step 102, method 100 completes.

With reference to FIGS. 4-9, a mapping relationship between QoS priorityclass and LBT priority class is described in details with Quality ClassIdentifier QCI and Data Radio Bearer DRB as examples.

First, LTE regulates nine Quality Class Identifier QCI and eight DataRadio Bearers DRBs to support necessary QoS supplies, wherein each QCIis characterized by priority, packet delay and acceptable packet loss.FIG. 4 gives detailed standardized QCI characteristics. Assuming LAAsupports smaller number of LBT priority classes (4 in FIG. 2) than thecurrent nine QCIs, there is a need to map each QCI value to the definedLBT priority classes, i.e., a mapping relationship between QCI and LBTis required.

Second, for LTE-LAA uplink, the user equipment needs to be configuredwith the mapping relationship between the multiple uplink traffics andthe LBT priority class. Based on this knowledge, the user equipmentcould select the corresponding LBT parameters corresponding to thetraffic type when only this traffic type is transmitted, or select theLBT parameters corresponding to the lowest LBT priority in case theintended downlink transmission burst with PDSCH contains trafficcorresponding to different LBT priority classes.

Also, under some circumstances, the mapping relationship is beneficialto be exchanged between neighboring intra-operator base stations forself-optimization purpose. The base station can semi-statically changeor configure the mapping relationship based on its own cell status aswell as the LBT parameters of its neighboring base station. Hence, it isdesired to design the mapping relationship as well as potentialsignaling to support different QoS in LTD-LAA.

To support multiple traffic services and QoS in LAA, based on a specificembodiment of the present disclosure depicted in FIG. 3, it proposes themapping table between the radio traffic service types and LBT priorityclass, wherein the mapping table could be set as default, or could besemi-statically changed and signaled. In FIG. 3, one category 4 LBTpriority class is defined by the minimum and maximum contention window(CW) sizes and the number of CCA slots in the defer period (n in FIG.3).

FIG. 4 illustratively shows standardized QCI characteristics. As shownin FIG. 4, QCI is classified into 1-9 priority levels in total anddivided into two groups corresponding to two resource types ofGuaranteed Bit Rate (GBR) and non-Guaranteed Bit Rate (non-GBR). Inaddition, FIG. 4 also depicts the priority, packet delay budge, packeterror loss rate and sample service corresponding to each numbered QCI.

FIG. 5 illustratively shows a diagram of a mapping mode between QCI andLBT priority class. As shown in FIG. 5, each QCI priority class is onlymapped to one LBT priority class. Those skilled in the art canunderstand that multiple QCI priority classes will be definitely mappedto one same LBT priority class because the number of LBT priorityclasses is smaller than the number of QCI priority classes in thespecific example. In addition, in the specific example depicted in FIG.5, QCI with a higher priority class is correspondingly mapped to the LBTwith a higher priority class.

FIG. 6 illustratively shows a specific example of the mappingrelationship between QCI and LBT priority class. In the specific exampleshown in FIG. 6, QCI 5 with the highest priority is mapped to the LBTpriority class 1 with the highest priority. Then, the higher QCIpriority classes 1-4 are mapped to LBT priority class 2, QCI priorityclasses 6-7 are mapped to LBT priority class 3 and the second lowest andthe lowest QCI priority classes 8-9 are mapped to LBT priority class 4.Those skilled in the art can understand that the mapping relationshipdepicted in FIG. 6 is just a specific example of the mappingrelationship between QCI and LBT priority class. The embodiments of thepresent disclosure are not limited to such specific mappingrelationship.

FIG. 7 illustratively shows a diagram of another mapping mode betweenQCI and LBT priority class. In the mapping mode depicted in FIG. 7, oneQCI priority class can be mapped to not only one LBT priority class, butalso multiple LBT priority classes. For example, QCI priority class Qmis mapped to two LBT priority classes Ln-1 and Ln in FIG. 7. As statedabove, in such case, the communication device working on an unlicensedfrequency band can select one from LBT priority classes Ln-1 and Ln totransmit the radio traffic when needed. It should be noted that thenumbers listed here are only for illustration purpose, and other numbersare also included within the scope of the present disclosure.

With reference to FIGS. 8-9, the mapping relationship between QoSpriority class and LBT priority class is described in details with DataRadio Bearer DRB as an example. Those skilled in the art can understandthat Signaling Radio Bearer SRB and DRB can be mapped in the samemanner. Therefore, the description will not go into details for SRB.

FIG. 8 illustratively shows a diagram of a mapping mode between DRB andLBT priority class. As shown in FIG. 8, each DRB identifier is onlymapped to one LBT priority class. Those skilled in the art canunderstand that multiple DRB identifiers will be definitely mapped toone same LBT priority class because the number of LBT priority classesis smaller than the number of DRB identifiers in the specific example.In addition, similar to the above description with QCI, each DBRidentifier can also be mapped to multiple LBT priority classes. In suchcase, the operation manner of the communication device working on anunlicensed frequency band is also similar and will not be repeated here.It should be noted that the numbers listed here are only forillustration purpose, and other numbers are also included within thescope of the present disclosure.

FIG. 9 illustratively shows a specific example of the mappingrelationship between DRB and LBT priority class. In the specific exampleshown in FIG. 9, DRB identifier 1 is mapped to the highest LBT priorityclass 1. Next, DRB identifiers 2-4 are mapped to LBT priority class 2,DRB identifiers 5-6 are mapped to LBT priority class 3 and DRBidentifiers 7-8 are mapped to the lowest LBT priority class 4 in theend. Those skilled in the art are can understand that the mappingrelationship depicted in FIG. 9 is just a specific example of themapping relationship between DRB and LBT priority class. The embodimentsof the present disclosure are not limited to such specific mappingrelationship.

FIG. 10 illustratively shows a communication device 1010 working on anunlicensed frequency band according to the embodiments of the presentdisclosure. In FIG. 10, dashed box indicates the unit is selectable. Asshown in FIG. 10, the communication device 1010 can comprise adetermining unit 101 and a transmitting unit 1020.

According to some embodiments of the present disclosure, a determiningunit 1010 can be configured to determine a mapping relationship betweenmultiple QoS priority classes and multiple Listen-Before-Talk (LBT)priority classes, wherein the multiple QoS priority classes are inone-to-one correspondence with multiple QoS requirements. Thetransmitting unit 1020 can be configured to transmit radio traffic basedon the mapping relationship.

According to some embodiments of the present disclosure, the mappingrelationship can comprise: mapping each QoS priority class only to oneLBT priority class.

According to some embodiments of the present disclosure, the mappingrelationship can comprise: mapping each QoS priority class to aplurality of LBT priority classes. In these embodiments, thetransmitting unit 1020 can be further configured to: select one of aplurality of LBT priority classes to which QoS priority class is mappedto transmit radio traffic.

According to some embodiments of the present disclosure, the mappingrelationship can comprise: causing a LBT priority class to which ahigher QoS priority class is mapped to be not lower than a LBT priorityclass to which a lower QoS priority class is mapped

According to some embodiments of the present disclosure, the mappingrelationship can be predefined.

According to some embodiments of the present disclosure, the mappingrelationship can be configurable. In these embodiments, there may be adefault mapping relationship. In these embodiments, the mappingrelationship can be semi-statically configurable.

According to some embodiments of the present disclosure, the mappingrelationship can be cell-specific. According to some embodiments of thepresent disclosure, the mapping relationship can be userequipment-specific.

According to some embodiments of the present disclosure, if each QoSpriority class is only mapped to one LBT priority class, thetransmitting unit 1020 can be further configured: when the radio trafficis associated with at least two LBT priority classes of the multiple LBTpriority classes, transmit radio traffic using a lower LBT priorityclass of the at least two LBT priority classes.

According to some embodiments of the present disclosure, thecommunication device 1000 can be a base station, and the determiningunit 1010 can be further configured to: configure a mapping relationshipbetween multiple QoS priority classes and multiple Listen-Before-Talk(LBT) priority classes. According to some embodiments of the presentdisclosure, the transmitting unit 1020 can be further configured to:transmit the mapping relationship to user equipment. Furthermore, thetransmitting unit 1020 can be further configured to: transmit themapping relationship to the user equipment via a broadcast message.Alternatively, the transmitting unit 1020 can be further configured to:transmit the mapping relationship to particular user equipment via auser equipment-specific message.

According to some embodiments of the present disclosure, thecommunication device 1000 can be a base station and if the mappingrelationship is configurable, the communication device 1000 can furthercomprise: a receiving unit 1030. The receiveing unit can be configuredto receive, from a neighboring base station, a mapping relationship usedby the neighboring base station; and the determining unit 1020 isfurther configured to configure the mapping relationship based onmapping relationship used by the neighboring base station.

According to some embodiments of the present disclosure, thecommunication device 1000 can be user equipment, and the determiningunit 1010 can be further configured to: receive the mapping relationshipfrom a base station. In these embodiments, the determining unit 1010 canbe further configured to: receive the mapping relationship from a basestation via a broadcast message. In these embodiments, the determiningunit 1010 can be further configured to: receive the mapping relationshipfrom a base station through a user equipment-specific message.

According to some embodiments of the present disclosure, the QoSpriority class can comprise Quality Class Identifier QCI. According tosome embodiments of the present disclosure, the QoS priority class cancomprise Data Radio Bearer DRB and/or Signaling Radio Bearer SRB.

In the description of the embodiments of the present disclosure, theterm “comprise” and other similar expressions indicate an inclusion inan open manner, i.e., “include, but are not limited to”. The term “basedon” represents “at least partly based on”. The term “an embodiment” or“the embodiment” means “at least one embodiment”.

It should note that the embodiments of the present disclosure can beimplemented by hardware, software or the combination of hardware andsoftware. The hardware part can be implemented by special logic whilethe software part can be stored in the memory and executed by anappropriate instruction execution system, such as a microprocessor orspecial-designed hardware. Those skilled in the art can understand theabove device and method can be implemented by means of computerexecutable instructions or within the processor control code, forexample, such code is provided for a programmable memory or data carriersuch as optical or electronic signal carrier.

Furthermore, although the drawings describe the operation of the methodof the disclosure in a specific sequence, it does not necessarilyrequire or suggest that the operation must be executed in the specificsequence or all shown operations must be executed to realize theexpected result. On the contrary, the order of the steps depicted in theflow chart can be altered. Additionally or alternatively, some steps canbe omitted or multiple steps can be combined into one step forexecution, and/or one step is disintegrated into multiple steps forexecution. It should also note that the features and functions of two ormore apparatuses in the disclosure can be materialized in one apparatus.Conversely, the feature and function of one apparatus described abovecan be materialized by multiple apparatuses.

Although the disclosure is described with reference to multiple specificembodiments, it should be understood that the present invention is notrestricted to the embodiments of the disclosure. The present disclosureaims to encompass all kinds of modifications and equivalent arrangementsincluded within the spirit and scope of the appended claims.

1. A method performed by a communication device working on an unlicensedfrequency band, comprising: determining a mapping relationship betweenmultiple quality of service (QoS) priority classes and multipleListen-Before-Talk (LBT) priority classes, wherein the multiple QoSpriority classes are in one-to-one correspondence with multiple QoSrequirements; and transmitting radio traffic based on the mappingrelationship.
 2. The method of claim 1, wherein the mapping relationshipcomprises: mapping each QoS priority class only to one LBT priorityclass.
 3. The method of claim 1, wherein the mapping relationshipcomprises: mapping each QoS priority class to a plurality of LBTpriority classes.
 4. The method of claim 3, wherein transmitting radiotraffic based on the mapping relationship comprises: selecting one of aplurality of LBT priority classes to which a QoS priority class ismapped to transmit the radio traffic.
 5. The method of claim 1, whereinthe mapping relationship comprises: causing a LBT priority class towhich a higher QoS priority class is mapped to be not lower than a LBTpriority class to which a lower QoS priority class is mapped. 6.-9.(canceled)
 10. The method of claim 1, wherein the mapping relationshipis cell-specific.
 11. The method of claim 1, wherein the mappingrelationship is user equipment-specific.
 12. The method of claim 2,wherein transmitting radio traffic based on the mapping relationshipcomprises: if the radio traffic is associated with at least two LBTpriority classes of the multiple LBT priority classes, transmitting theradio traffic using a lower LBT priority class of the at least two LBTpriority classes.
 13. The method of claim 1, if the communication deviceis a base station, determining a mapping relationship between multipleQoS priority classes and multiple LBT priority classes comprises:configuring the mapping relationship between the multiple QoS priorityclasses and the multiple LBT priority classes.
 14. The method of claim13, further comprising: transmitting the mapping relationship to userequipment. 15.-16. (canceled)
 17. The method of claim 13, furthercomprising: receiving, from a neighboring base station, a mappingrelationship used by the neighboring base station; and configuring themapping relationship based on the mapping relationship used by theneighboring base station.
 18. The method of claim 1, if thecommunication device is user equipment, determining a mappingrelationship between multiple QoS priority classes and multiple LBTpriority classes comprises: receiving the mapping relationship from abase station. 19.-20. (canceled)
 21. The method of claim 1, wherein theQoS priority class comprises Quality Class Identifier (QCI).
 22. Themethod of claim 1, wherein the QoS priority class comprises Data RadioBearer (DRB) and/or Signaling Radio Bearer (SRB) and/or a physical layersignaling.
 23. A communication device working on an unlicensed frequencyband, comprising: a determining unit configured to determine a mappingrelationship between multiple quality of service (QoS) priority classesand multiple Listen-Before-Talk (LBT) priority classes, wherein themultiple QoS priority classes are in one-to-one correspondence withmultiple QoS requirements; and a transmitting unit configured totransmit radio traffic based on the mapping relationship. 24.-44.(canceled)